KR20200116780A - LED optical system with adjustable divergence angle - Google Patents

Abstract

The present invention relates to an LED optical system including an LED light source, a reflector, a lens, a radiating body, and an external body. The LED light source includes two or more LEDs and has a configuration of selectively lighting the LED to control light distribution (beam pattern) and a beam angle (beam angle). In addition, by changing the arrangement of each LED constituting the LED light source or each LED package, or controlling and varying the beam angle through brightness control of each LED or each LED package, thereby implementing even a very narrow beam angle of around 1 degree of the beam angle. An LED condensing optical system of the present invention can be applied to an LED searchlight in the form of arranging a plurality of such LED condensing optical systems.

Description

LED optical system with adjustable divergence angle

Optical systems are devices that emit parallel rays in a specific direction, and are used for landscape lighting, stage lighting, and searchlighting. Optical systems used in marine searchlights are used for lifesaving, patrol, surveillance, and alert purposes. Depending on the type of optical system, the optical reach ranges from several tens of meters (m) to several kilometers (Km).

Traditionally, as a light source of an optical system, a lamp with high power and easy condensation such as metal halide and halogen has been used, and a device using an LED, which is characterized by low power consumption and long life, is being used. The beam spot formed on the surface to which light is irradiated has been adjusted by changing the position of the light source regardless of the type of light source or by changing the design of the lens and the reflective surface. When LED is applied to an optical system, several LED packages are required to obtain high output.

The conventional optical system structure is a case of using a lamp-type light source (eg, metal halide, halogen, etc.) that uses a parabolic reflector for condensing (Fig. 15), and an LED combined with a lens. There is a case where a light source is used (Fig. 16). The conventional LED optical system structure to which the condensing lens is applied is not a structure capable of varying the condensing angle, so there is a functional limitation that cannot widen or narrow the beam angle.

The LED optical system of the present invention includes an LED light source, a reflector, a lens, a heat dissipation case, and an outer case, and the LED light source includes two or more LEDs, and the LEDs are selectively lit to light distribution (beam pattern) and directivity ( beam angle). The LEDs constituting such an LED light source are more than one type, and can be composed of one type of various LEDs including micro LEDs, mini LEDs or SMD LEDs, and can be composed of two types or three or more types of LEDs as necessary. have.

In the LED optical system of the present invention, the current supplied to the LED is controlled for each LED. Accordingly, the size of the LED light-emitting surface formed by the LED light source of the LED optical system can be adjusted by controlling the current. In addition, the shape of the LED light-emitting surface constituted by the LED light source of the LED optical system can also be adjusted by controlling the current.

In the LED optical system of the present invention, the LED light source is characterized by two or more. One LED light source is made of a plurality of LEDs, and lLED light sources made of a plurality of LEDs may be disposed.

In the LED optical system of the present invention, the two or more LEDs are adjacent, and the glitch can be controlled by controlling the current of the adjacent LEDs. Glitch is a discontinuous light distribution phenomenon between LED and LED caused by the difference in peak light intensity of each LED.

In the LED optical system of the present invention, the LED light source may be composed of two or more LEDs having the same size. The LED light source of the present invention may be selected from various types of LEDs including micro LEDs or mini LEDs or SMD LEDs, and the selected LEDs have the same size and may constitute a light source.

In the LED optical system of the present invention, the size of the LED constituting the LED light source may be two or more types. The LED light source of the present invention may be selected from various types of LEDs including micro LEDs or mini LEDs or SMD LEDs, and the light source may be configured with LEDs having two or more different sizes selected.

In the LED optical system of the present invention, the arrangement of two or more LEDs constituting the LED light source may be any one of a linear, orthogonal, or radial. Such an arrangement may be symmetrical or asymmetrical or radial or concentric, and may be formed on a plane and a three-dimensional surface.

In general, a lens or reflector is applied to an optical system for condensing (hereinafter, a condensing optical system), and the shape of the lens and reflector is changed to change the beam angle. Or, a method of applying and controlling multiple optical systems is applied. Alternatively, the beam angle can be changed by changing the position of the light source in the optical system, but the overall beam distribution may not be smooth, such as unwanted light distribution or noise. have. Glitch (a discontinuous light distribution between the LED and the LED caused by the difference in the peak light intensity of the LED) is an example. However, the present invention controls and varies the beam angle through the arrangement and brightness control of each LED or each LED package constituting an LED light source, thereby providing a very narrow beam angle of around 1 degree. Can be implemented. In the form of arranging a plurality of the LED condensing optical systems of the present invention, it can be applied to an LED light source searchlight.

1 is a basic structure of the LED condensing optical system
2 is a conventional condensing optical system
3 is an embodiment of the present invention
4 is an example of a directivity angle distribution of the present invention
Figure 5 is an example of the orientation angle distribution of the present invention
Figure 6 is an example of the orientation angle distribution of the present invention
7 is an illustration of the present invention
8 is an illustration of the present invention
9 is an illustration of the present invention
10 is an illustration of the present invention
11 is an illustration of the present invention
12 is an illustration of the present invention
13 is an example of the structure of a conventional condensing optical system
14 is an example of the structure of a conventional condensing optical system
15 is an example of controlling a beam angle in a conventional condensing optical system
16 is an embodiment of the present invention (LED light source searchlight)

The configuration of the LED condensing optical system of the present invention includes an LED light source (2), a reflector (a condensing reflector) (4), a transparent cover (5), a heat transfer body (3), and an external body. Includes (1) (Fig. 1, the power connection wiring part is omitted). The LED light source includes two or more LEDs (a package composed of individual LEDs or a package composed of multiple LEDs). The condensing reflector is a part that reflects the light emitted from the LED light source and condenses it to the front.It has a straight or curved shape, and if the shape of the curved surface is parabolic, the LED light source is located at the focal point of the parabolic surface. . The transparent cover is a part where the light reflected from the condensing reflector is finally transmitted to the outside and is made of materials such as plastic, glass, and silicone. The heat dissipation body is a part that discharges the heat emitted from the LED light source to the outside, and has a structure in which a part is exposed outside the external body or integrated with the external body.

The configuration and control method for controlling the beam angle of such an LED condensing optical system are as follows. In the conventional LED condensing optical system shown in FIG. 2, one light source is applied to the center of the optical system to minimize (converge) the beam angle to minimize the size of the light emitting surface of the light source, and the light distribution and beam angle ( Beam patten and angle) are fixed to one result value (Figs. 13, 14, 15). In the present invention, an auxiliary LED (8: LED B) is disposed in addition to the basic LED (7: LED A) located at the center of the optical system as shown in FIG. 3 to control the beam angle. At this time, the auxiliary LED 8 may be disposed symmetrically or asymmetrically. By controlling the current applied to LED A and LED B, the brightness of each LED is controlled at a certain ratio. By this driving method, the brightness of each LED is relatively adjusted to control the light distribution and beam angle finally emitted from the condensing optical system (Figs. 4, 5, 6).

This condensing optical system can be driven as follows. As the brightness of LED A becomes larger than that of LED B, the beam angle decreases. To minimize the beam angle, turn off the driving of LED B and set the brightness to zero. On the other hand, if the brightness of LED B is gradually increased, the beam angle can be gradually increased. FIG. 4 shows the distribution of radiated light (Beam) when the light amount ratio of LED A and LED B is 1:0 (only LED A is driven and LED B is off). At this time, the beam angle is 1.5 degrees. FIG. 5 is a case in which the light amount ratio of LED A and LED B is a beam distribution of 1:10, and the beam angle is 3.4 degrees, and the beam angle is relatively larger than that of FIG. 4. 6 shows the distribution of radiation when the light amount ratio of LED A and LED B is 1:15, and the beam angle is 5.9 degrees. It can be seen from FIGS. 4 to 6 that the beam angle gradually increases according to the difference in the light amount ratio.

Accordingly, in the LED optical system of the present invention including an LED light source, a reflector, a lens, a heat dissipation body, and an external body, the LED light source includes two or more LEDs, and the LED is selectively lit to light distribution (beam pattern) and beam angle. (beam angle) is controlled. The LEDs constituting such an LED light source are more than one type, and can be composed of one type of various LEDs including micro LEDs, mini LEDs or SMD LEDs, and can be composed of two types or three or more types of LEDs as necessary. have. In addition, in the LED optical system of the present invention, the current supplied to the LED is controlled for each LED. Accordingly, the size of the LED light-emitting surface formed by the LED light source of the LED optical system can be adjusted by controlling the current. In addition, the shape (or arrangement) of the LED light-emitting surface constituted by the LED light source of the LED optical system can be controlled by controlling the current. In addition, in the LED optical system of the present invention, the two or more LEDs are adjacent, and the glitch can be controlled by controlling the current of the adjacent LEDs. Glitch is a discontinuous light distribution phenomenon between the LED and the LED caused by the difference in the peak light intensity of the LED. In addition, in the LED optical system of the present invention, the LED light source is characterized by two or more. One LED light source is made of a plurality of LEDs, such an LED light source made of a plurality of LEDs may be arranged.

In the LED optical system of the present invention, the LED light source may be composed of two or more LEDs having the same size. The LED light source of the present invention may be selected from various types of LEDs including micro LEDs or mini LEDs or SMD LEDs, and the selected LEDs may have the same size (FIGS. 9 to 10). 3, 7, and 12 show an LED light source in which a plurality of LEDs having different sizes are disposed. In the LED optical system of the present invention, the size of the LED constituting the LED light source may be two or more types. That is, the LED light source of the present invention may be selected from various types of LEDs including micro LEDs or mini LEDs or SMD LEDs, and the selected LEDs may have two or more different sizes.

8 to 11 show a change in the shape of the beam spot formed according to the lighting state of each LED constituting the light source in the present invention using an LED package composed of a plurality of LEDs as a light source. This is the simulation result showing. LEDs (single LED or LED package) constituting the LED light source may use micro LEDs or mini LEDs as an example, and by arranging these LEDs, the LEDs can be driven for each area (examples in FIGS. 8 to 11: green ( LED on), blue (LED off)). 16 shows an actual beam spot formed by an embodiment reflecting these contents.

The LED (package) constituting the LED light source can be arranged by mixing micro LEDs and general high power LEDs as an example (hybrid type), and selective driving is possible for each area (example in FIG. 12: green ( LED on state), blue (LED off state)) (Figs. 7 to 11).

In addition, in the LED optical system of the present invention, the arrangement of two or more LEDs constituting the LED light source may be any one of linear, orthogonal, and radial. Such an arrangement may be symmetrical or asymmetrical or radial or concentric, and may be formed on a plane and a three-dimensional surface. A plane means two-dimensional, and a three-dimensional space is a three-dimensional space including a curved surface. In addition, the array of LEDs constituting the LED light source may be configured by mixing a flat surface and a three-dimensional surface (FIGS. 3 and 7 to 12).

The detailed description of the present invention and the contents disclosed in the drawings are examples and examples for explaining the claims of the present invention. These examples and examples do not limit the scope of the present invention, and variations of these examples and examples belong to the scope of the present invention.

1: external body
2: LED light source
3: Heatsink
4: reflector (condensing reflector)
5: Transparent cover
6: PCB
7: LED A
8: LED B
9: LED on status
10: LED off state
11: Micro LED (sub light source) off
12: Micro LED (sub light source) on
13: General high power LED (main light source)
14: lens

Claims (7)

In the LED optical system including an LED light source, a reflector, a lens, a radiating body, and an external body,
The LED light source includes two or more LEDs, the LED optical system for controlling the light distribution and directivity angle by selectively lighting the LED. The method of claim 1,
LED optical system, characterized in that controlling the current supplied to the LED for each LED. The method of claim 1,
LED optical system, characterized in that the LED light source is two or more. The method of claim 1,
The two or more LEDs are adjacent to each other, LED optical system, characterized in that to control the glitch by controlling the current of the adjacent LED. The method of claim 1,
LED optical system, characterized in that the size of two or more LEDs constituting the LED light source are the same. The method of claim 1,
LED optical system, characterized in that the size of the LED constituting the LED light source is two or more. The method of claim 1,
An LED optical system, characterized in that the arrangement of two or more LEDs constituting the LED light source is any one of a linear, orthogonal, or radial.

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